I have a scientific code that uses both sine and cosine of the same argument (I basically need the complex exponential of that argument). I was wondering if it were possible to do this faster than calling sine and cosine functions separately.

Also I only need about 0.1% precision. So is there any way I can find the default trig functions and truncate the power series for speed?

One other thing I have in mind is, is there any way to perform the remainder operation such that the result is always positive? In my own algorithm I used `x=fmod(x,2*pi);`

but then I would need to add 2pi if x is negative (smaller domain means I can use a shorter power series)

EDIT: LUT turned out to be the best approach for this, however I am glad I learned about other approximation techniques. I will also advise using an explicit midpoint approximation. This is what I ended up doing:

```
const int N = 10000;//about 3e-4 error for 1000//3e-5 for 10 000//3e-6 for 100 000
double *cs = new double[N];
double *sn = new double[N];
for(int i =0;i<N;i++){
double A= (i+0.5)*2*pi/N;
cs[i]=cos(A);
sn[i]=sin(A);
}
```

The following part approximates (midpoint) sincos(2*pi*(wc2+t[j]*(cotp*t[j]-wc)))

```
double A=(wc2+t[j]*(cotp*t[j]-wc));
int B =(int)N*(A-floor(A));
re += cs[B]*f[j];
im += sn[B]*f[j];
```

Another approach could have been using the chebyshev decomposition. You can use the orthogonality property to find the coefficients. Optimized for exponential, it looks like this:

```
double fastsin(double x){
x=x-floor(x/2/pi)*2*pi-pi;//this line can be improved, both inside this
//function and before you input it into the function
double x2 = x*x;
return (((0.00015025063885163012*x2-
0.008034350857376128)*x2+ 0.1659789684145034)*x2-0.9995812174943602)*x;} //7th order chebyshev approx
```

`cos^2(x) + sin^2(x) = 1`

. Pythagorean identity.`sincos`

which does what you want. But at the same kind of precision as you'd expect from a call to`sin`

or`cos`

so perhaps not meeting your requirements. I think this is provides programming-language-level access to a member of the x86 instruction set.`0.1% precision`

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